Multi-tiered incremental software updating

ABSTRACT

A software application ( 110 ) is updated to a newer version by means of incremental update patches ( 122 ). The incremental update patches ( 122 ) each contain that information necessary to transform one version of an application to another version. Any version of an application ( 110 ) may be upgraded to any other version of the application, through the use of a series of incremental update patches ( 122 ). The appropriate incremental update patches ( 122 ) are distributed in a multi-tiered manner, such that some update patches ( 122 ) update the application ( 110 ) by only one version, and others update the application ( 110 ) by several versions.

CROSS-REFERENCE TO RELATED APPLICATIONS

The present patent application is a continuation of U.S. patentapplication Ser. No. 09/469,582 filed Dec. 22, 1999, now U.S. Pat. No.6,651,249, which is a division of U.S. patent application Ser. No.09/047,949 filed Mar. 25, 1998, now U.S. Pat. No. 6,052,531.

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates generally to incremental softwareupdating, and more specifically to a system and method for using anautomated, multi-tiered approach to performing incremental softwareupdates.

2. Description of Background Art

Some computer software publishers update their software “applications”(computer programs and data files associated with the programs)frequently. For some types of software applications, such as virusprotection software, these updates are particularly frequent. Virusprotection software applications are designed to detect computer viruseson a computer system, and may also remove viruses which are found. Anexample of such a software application is Norton Anti-Virus, publishedby Symantec Corporation of Cupertino, Calif. Because these virusprotection software applications rely on data about specific viruses,and new viruses are constantly being written to avoid current virusdetection capabilities, it is necessary to update virus protectionsoftware applications on a regular basis to account for the newestviruses. Frequent updating of data files is also necessary for somedatabase publishers, who must put up-to-date information in theirdatabases, and remove obsolete information therefrom. Periodic updatingof general software applications to expand capabilities and eliminate“bugs” is also common.

Currently, several methods are used to update software applications. Thesimplest of these is to distribute one entire software application toreplace an older one. This method, the “full update” method, is simple,but expensive and inconvenient. Typically the software is distributed onsome type of removable media, such as floppy disks or CD-ROMs, which arecostly to produce and distribute. The time an end user must wait for theremovable medium to arrive and the time it takes for the softwareapplication to install itself on a computer system are inconvenient.This inconvenience is compounded where updates occur frequently. Becauseof the large size of software applications it is generally not feasibleto distribute such updates over computer networks, such as the Internet.When full updates are distributed over the Internet, they often causesuch high loads on servers that other users suffer slow-downs on thenetwork, and the servers have trouble meeting the demands.

In order to bypass many of the problems associated with this type ofsoftware updating, some software publishers distribute “incrementalupdates.” These updates do not contain entire software applications, butrather only that information necessary to transform a given version of asoftware application to a newer version. Among the methods available toperform such incremental software updating is binary patching, performedby programs such as RTPatch, published by Pocket Soft, Inc. A binarypatcher replaces only those binary bits of a software application whichare different in a newer version. Because most software updates involvechanges to only a small portion of a software application, a binarypatcher needs, in addition to the old software application, only a smalldata file including the differences between the two versions. Thesmaller data files distributed for a binary patch update are often lessthan 1% of the size of a full update, taking advantage of the largeamount of redundancy in the two versions.

The use of incremental update methods allows for smaller updates whichcan be distributed by means that are not conducive to the distributionof full updates, such as distribution over the Internet. The smallerincremental updates also make distribution by floppy disk more feasiblewhere a full update would have required many disks, and an incrementalupdate may require only one. However, incremental update methodsintroduce another problem: the incremental update is specifically usefulfor updating only one particular version of a software application toanother particular version. When updates occur frequently, as with virusprotection software applications, end users may often update from anarbitrarily old version to the newest version, skipping over severalpreviously released versions. An incremental update for the newestversion of a software application will update only from the most recentversion, however.

One solution to this problem has been for software publishers to group anumber of binary patch data files together into one distribution. Theuser of an arbitrarily old version can then apply each incrementalupdate, one at a time, to update to the newest version. However, thenumber of incremental updates may be large, due to the fact that thegrouping covers a large number of versions. The benefits of smallerdistributed update files begin to disappear, as the size of thegrouped-together incremental updates grows. This method of updatingapplications can also be cumbersome, as a series of update patches needto be selected from the group and applied to the software applicationone after another.

Another solution to the problem of incremental updateversion-specificity has been to create a unique patch file fortransforming every previous version of the application to the mostcurrent version. Some users may not wish to update their softwareapplications to the most current version, however, for a number ofreasons. Some may be within a corporate setting, where an informationservices department allows updates only to versions it has had a chanceto test and approve. Others may have older computer systems which do notsupport the increased resource requirements of the newest version of anapplication. For these reasons, publishers of software updates usingthis method must generally keep updates available from every previousversion of an application to a large number of more recent versions.This results in a geometrically growing number of update patch files toproduce, store and maintain for users. In the case of publishers whoupdate their applications frequently, such as publishers ofvirus-protection software applications, this may quickly becomeuntenable.

One alternative to the methods described above is the use of “push”technology, in which servers maintain databases of what versions of asoftware application each user has. The servers then send the necessaryupdates to each user, as they become available. This system requires“smart” servers, however, to monitor user configurations, determine whateach user needs, and send the appropriate update information. Thisresults in a server-intensive system which can cause a drain on serverresources comparable to that experienced in the full update scheme, whenmany users are simultaneously requesting full updates.

What is needed is a system for updating software applications from anarbitrary first version to an arbitrary second version which does notrequire a large amount of information to be stored and maintained by asoftware publisher, does not require the user to acquire a large amountof data to perform such an update, and does not require the use of“smart” servers.

DISCLOSURE OF INVENTION

The present invention is a method and apparatus for distributing theappropriate incremental software update information to users. A softwarepublisher (118) provides update patches (122) which will update users'software applications (110) from one state to another. The updatepatches (122) are ‘tiered.’ Update patches on the first tier (200)update from a given application state to the subsequent applicationstate. Update patches on the second tier (202) update an applicationfrom a given state to the state which is two versions later. The tier ofan update patch indicates how many individual updates are spanned by thepatch.

By selectively providing tiered update patches, software publishers(118) can facilitate quick, efficient updating of users' applications(10) without producing and maintaining large numbers of update patches(122). These update patches (122) may be provided to userssimultaneously through a variety of distribution channels (124), since a“smart server” is not necessary to provide users with the needed updatepatches (122). This allows for selective redundancy, as update patches(122) which are likely to be needed by many users may be made availablethrough more of the available distribution channels (124) than others,providing a robust distribution system.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other more detailed and specific objects and features of thepresent invention are more fully disclosed in the followingspecification, reference being had to the accompanying drawings, inwhich:

FIG. 1 is a block diagram of a first embodiment of the presentinvention, in which a software application 110 on a user's computer 116is updated with incremental update patches 122 from a remote source1118.

FIG. 2 is an illustration of the relation of various tiers of updates toa series of application states in the present invention.

FIG. 3 is an illustration of an example of the use of multi-tieredincremental updates to perform a software application update accordingto the present invention.

FIG. 4 is an illustration of an example of a sub-optimal softwareapplication update using incremental updates.

FIG. 5 is an illustration of an example of a publishing schedule formulti-tiered incremental updates which meets the necessary condition foroptimal updates according to the present invention.

FIG. 6 is an illustration of an updating program 126 using a catalog 404to determine an appropriate sequential set of update packages 412 basedon attributes of an application 110.

FIG. 7 is an illustration of an updating program 126 constructing asorted directory 408 of available catalogs 404 from different sources400 and 402.

FIGS. 8 a and 8 b are a flowchart showing how an updating programdetermines what update patches need to be applied to effect an update,and how the updating program carries out the updating.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

In one embodiment, the present invention may be implemented as an updatemechanism for a virus protection software application. In otherembodiments, the present invention may be used to update generalcomputer readable files, which may include data files, program files,database files, graphics files, or audio files. For illustrativepurposes only, the invention will be described as embodied in an updatemechanism for virus protection software.

Referring to FIG. 1, a virus protection software application 110 whichincorporates a number of virus detecting routines 112, and utilizes anumber of data files containing virus information 114, is installed on auser's computer 116. Because of the rate at which new viruses arecreated, it is desirable to update the virus protection softwareapplications on the user's computer frequently. These updates could takeplace as often as daily, or even more frequently if desired. Generally,these updated applications 110 will include only small changes to thedata files 114, but sometimes larger changes to the virus detectingroutines 112 will also be included.

In order to fully describe the embodiment of the present invention, itis first necessary to describe DeltaPackages, DeltaCatalogs, andDeltaDirectories.

DeltaPackages

Each time an updated software application 110 is produced by the virusprotection software publisher, the updated form of the softwareapplication constitutes a new version. The software publisher uses anincremental update builder, such as binary patch file builder 120, toproduce at least one incremental update, such as binary patch file 122,which can transform a previous version of the software application tothe current version. A binary patch file builder 120 is a program whichtakes two versions of a software application, for example versions A andB, and produces a binary patch file, 122, which can be used with versionA of the software application to produce version B. In this example,version A would be the “source” state and version B would be the“destination” state of the application. This binary patch file 122 caneither be an executable file which acts directly on version A of thesoftware application, or it can be a data file which is used by aseparate binary patch program (not shown) to transform version A of thesoftware application to version B. The binary patch files 122 are storedon an update data source 124 (a “server”) which makes the patch files122 available to an updater program 126 (a “client”). The updaterprogram 126 determines what patch files 122 are necessary, retrievesthem and applies them to the application to be updated 110. In theillustrative embodiment, the incremental update files are binary patchfiles which are digitally signed compressed executable modules, and theJava ARchive (JAR) platform-independent file format, available from SunMicrosystems, is used for this purpose. Because they are digitallysigned, the authenticity of the updates can be ensured. When executed,the incremental update file automatically transforms a softwareapplication from a source state to a destination state. Theseself-contained executable incremental update files conforming to the JARformat are referred to as “DeltaPackages” 122, and are one example ofwhat is referred to herein as an “update patch”.

In FIG. 2, a series of application states are given, designated state Athrough state S. Each application state is a software applicationversion which is produced by the software publisher later in time than aversion with an alphabetically earlier letter designation. TheDeltaPackages 122, which are referred to as “tier 1” DeltaPackages 200,are so named because they each effect a transition from an applicationstate which is only one version earlier than the destination state.There is a tier 1 DeltaPackage 200 for updating to each applicationstate other than the initial application state, A. The softwarepublisher may produce higher tier DeltaPackages 122, such as “tier 3”DeltaPackages 202 and “tier 9” DeltaPackages 204. A tier 3 DeltaPackage202 is used to transform an application from a source state threeversions earlier than the destination state, and a tier 9 DeltaPackage204 is used to transform an application from a source state nineversions earlier than the destination state. Many other tiers ofDeltaPackages 122 may be produced, but the benefits of additional tiersmust be weighed against the costs, described below. In FIG. 2, tier 1DeltaPackages 200 are produced for each new version, tier 3DeltaPackages 202 are produced for every third version, and tier 9DeltaPackages 204 are produced for every ninth version.

For illustrative purposes, each DeltaPackage 122 is given a designationwhich is “A” followed by two letters. The first letter indicates theapplication source state upon which the DeltaPackage 122 works and thesecond letter indicates the application destination state produced. Forthe case where there are not multiple “flavors” of the application whichneed to be updated in parallel, a relatively simple process is employedto update the application. DeltaPackages 122 are applied to a user'ssoftware application incrementally, beginning with the highest tierDeltaPackage 122 available which has a source state equal to the currentstate of the application, and a destination state no later than thedesired ending state. After the DeltaPackage 122 is applied, and theapplication is updated to the destination state of the DeltaPackage 122,another DeltaPackage 122 is chosen in the same manner, with the newapplication state providing the source state of the next DeltaPackage122. This continues until the desired ending state of the application isreached.

FIG. 3 illustrates this procedure for a case in which it is desired totransform an application of state F to an application of state T.Following the procedure described above, such a transformation isaccomplished through only four incremental updates, from F to G to J toS to T. Each time a new DeltaPackage 122 is to be selected, the onechosen is the highest tier DeltaPackage 122 with the current applicationstate as a source state, and a destination state which does not exceedthe desired ending state.

When fewer incremental updates are required to perform a giventransformation, fewer DeltaPackages 122, and therefore less information,needs to be transferred to the application. The procedure describedabove produces a desired transformation using the smallest number ofavailable DeltaPackages 122, as long as one condition is met: noavailable DeltaPackage 122 may have a source state which is between thesource and destination states of an available DeltaPackage 122 with alower tier. As long as this condition is met, then the proceduredescribed above will perform an optimum transformation, using thesmallest number of available DeltaPackages 122 to get from the beginningstate to the desired ending state. If the condition is not met then theprocedure described above may result in a transformation which uses moreof the available DeltaPackages 122 than necessary. An example of asub-optimal transformation is illustrated in FIG. 4. In that case, atransformation from state G to state S uses four DeltaPackages 122 (ΔGJ,ΔJM, ΔMP and ΔPS), when it need only use three (ΔGH, ΔHI, and ΔIS).Because the ΔIS DeltaPackage 122 has a source state (I) which is betweenthe source and destination states of a lower tier DeltaPackage (ΔGJ),the ΔIS DeltaPackage 122 violates the above condition, and a sub-optimalset of DeltaPackages 122 is used. In practice, a software publisher mayeasily ensure that the available DeltaPackages 122 meet this condition,since each DeltaPackage 122 is produced later in time than DeltaPackages122 with earlier destination states. In the above example, beforeissuing DeltaPackage ΔIS, the publisher would eliminate DeltaPackage ΔGJand possibly replace it with another, such as DeltaPackage ΔGI.

In the example of FIG. 3, if only the tier 1 DeltaPackages 200 had beenavailable, fourteen DeltaPackages 122 would have been required for thetransformation, instead of four, and much unnecessary information wouldhave been transferred to the application. The total number ofDeltaPackages 122 which would have been produced by the publisher,however, would have been smaller, the higher tier DeltaPackages 122 nothaving been produced. On the other hand, if a tier 14 DeltaPackage 122designated ΔFT had been available, only one DeltaPackage 122 would havebeen required, and very little information would have been transferredto the user. However, the availability of a DeltaPackage 122 whichaccomplishes any particular transformation in one step can be assuredonly by producing individual DeltaPackages 122 from every source stateto every destination state, which requires a number of DeltaPackages 122approaching N! (where N is the number of file states). Producing andmaintaining such a large number of individual DeltaPackages 122 is notfeasible in many situations, as explained above. These considerationsmust be considered by a software publisher in determining the mostefficient DeltaPackage 122 publishing schedule. For the illustrativeembodiment, it was determined that providing DeltaPackages 122 of tiers1, 3 and 9 would be most efficient.

The tiers of DeltaPackages 122 produced do not need to be publishedaccording to any fixed schedule, but rather may be determined as newupdates become available. In FIG. 5 an irregular publishing schedule ofDeltaPackages 122 is shown. There are four separate tiers ofDeltaPackages 122 available with J as a source state. The decision tocreate so many DeltaPackages 122 with the same source state may be basedon the fact that many copies of the application in the J state are knownto be at large. Many publisher-specific, application-specific, andinformation transport mechanism-specific factors will affect thedesirability of a publishing schedule for DeltaPackages 122.

DeltaCatalogs

Software publishers often produce different “flavors” of a singlesoftware application, directed to different computer architectures,different operating systems, and users who speak different languages.The scheme for publishing incremental updates laid out above is adequatefor the case in which there is only one flavor of a softwareapplication. For the more general case of several application flavors,however, some additional mechanisms can be used to handle the additionalcomplexities of parallel updating. A system which addresses thesecomplexities is described in the second illustrative embodiment of thepresent invention.

In the case of virus definition updates, there are often updates whichare not operating system-specific, and sometimes there are updates whichare not even computer architecture-specific. Other times, updates arespecific to these, and other, categories. A single update DeltaPackage122 may be useful to update some flavors of an application, but notothers. To handle these complexities, update catalogs, referred to as“DeltaCatalogs,” are utilized. These update catalogs are another exampleof what are referred to herein as “update patches.” Rather than having asingle DeltaPackage 122 correspond to each incremental update (i.e.“ΔIS”) as above, a DeltaCatalog corresponds to each incremental update(i.e. “ΔIS”). Each DeltaCatalog has an associated source state and anassociated destination state, and specifies the necessary updateinformation by specifying which DeltaPackages 122 should be used by eachflavor of the application to update from the source state to thedestination state. In one embodiment, DeltaPackages 122 are given uniqueIDs which do not conform to the “ΔAB” format used above for illustrativepurposes, and are specified by the DeltaCatalogs using these unique IDs.With DeltaCatalogs substituted for DeltaPackages 122, the general schemedescribed above is utilized.

There are a number of different ways DeltaCatalogs can be implemented.In this embodiment, the Extensible Markup Language (XML) standard isused to create a document type definition. The XML standard is availablefrom W3C Publications, World Wide Web Consortium, MassachusettsInstitute of Technology, Laboratory for Computing Sciences, NE43-356,545 Technology Square, Cambridge, Mass. 02139. An example document typedefinition corresponding to the XML standard, referred to as DPML (forDeltaPackage Markup Language), is given in Appendix A. In this documenttype definition, there are a number of types of entries a DeltaCatalogmay contain. These types are Product (the type of software application),Package (a specific DeltaPackage 122), OS (operating system), CPU(computer architecture) and Language (the language spoken by the usersof the software application). An entry of any of these types exceptPackage may in turn contain entries of the types Product, Package, OS,CPU or Language. None of the entry types may contain a DeltaCatalog, andthe Package must contain an “ID” which corresponds to a specificDeltaPackage 122. Also, the “to”, or destination state, data field andthe “from”, or source state, data field must be given for aDeltaCatalog.

An example of a DeltaCatalog contained in a file written to conform tothe XML format is given in Appendix B. In the DeltaCatalog file itself,the document type definition for “DPML” is specified by including auniform resource locator (URL) pointing to the location of a currentspecification of the document type definition. Alternatively, the datatype definition may be included in the file explicitly. A softwareapplication to be updated contains the attributes of current state,Product, OS, CPU, and Language, and has access to the desired endingstate of the software application, as described below. In order todetermine a sequential set of DeltaPackages 122 which need to be appliedto the software application to effect the transformation from thecurrent state to the desired ending state, an updating mechanism,referred to as a “DeltaUpdater” is used. The DeltaUpdater may be aseparate program, or may be part of the software application itself. Itgoes through the same basic procedure outlined above, with DeltaCatalogstaking the place of DeltaPackages 122. The DeltaCatalog of the highesttier available which has a “from” field matching the application'scurrent state and which has a “to” field which does not exceed theending state is selected by the DeltaUpdater. The DeltaCatalog is thenprocessed, with the DeltaUpdater processing only those sub-entriescontained within entries with attributes which match those of theapplication. An example is illustrated in FIG. 6. The DeltaCatalog 404contains a simplified form of the information contained in theDeltaCatalog file of Appendix B. Application 110 has the attributes of“NAV version 2.0 running on Windows NT on an alpha computer using NorthAmerican English.” The DeltaUpdater 126 would process only Package ID's“487” and “766,” as all other Package entries correspond to differentattributes. Those DeltaPackages 122 which correspond to these two IDswould then makeup a sequential set 412 of DeltaPackages 122 to beapplied to application 110 in the order they were encountered inDeltaCatalog 404. When applied to application 110, the DeltaPackages 122of set 412 transform application 110 from state 1 to state 8, the statesgiven in the “from” and “to” fields of DeltaCatalog 404. If the desiredending state were still later than state 8, then this procedure wouldagain be applied to select and process another DeltaCatalog 404, onewhich has a “from” value of 8.

DeltaDirectories

A number of transfer mechanisms are available to a DeltaUpdater forretrieving DeltaCatalogs and DeltaPackages 122. Among these are the NNTPUsenet server protocol, available from Internic as “Request For Comments977”; the HTTP protocol, available from Internic as “Request ForComments 1945”; the FTP protocol, available from Internic as “RequestFor Comments 959”; and direct access to a “file server” using a protocolsuch as the Universal Naming Convention (UNC). A file server may be,among other things, internal disk media, removable disk media, or anetwork resource. Other distribution mechanisms are currently availableand more will likely be available in the future. All that is required ofa transfer mechanism is that the mechanism be able to supply computerreadable data upon request. The present invention utilizes so called“dumb media,” meaning that the medium supplying the requestedinformation need not interact with the DeltaUpdater beyond simplysupplying requested data. Specifically, “smart servers,” such as thoseused in “push” technology, are not necessary. A smart server determineswhat update information is necessary, given information about the stateof the software application, and then supplies that information. Thedescribed transfer mechanisms allow DeltaCatalogs and DeltaPackages 122to be retrieved from “catalog sources” and “update data sources” onwhich they are stored.

A typical system embodying the present invention will have availablemore than one of the mentioned transfer mechanisms, as illustrated inFIG. 7. A DeltaUpdater 126 will have access to a list 403 of locations,specified as URLs, where needed data may be found. In general, theseURLs will specify a number of NNTP news-servers with news-groups, HTTPservers with directory paths, FTP servers with directory paths, and fileservers with directory paths. In the embodiment illustrated in FIG. 7,an NNTP server 400 and a file server 402 contain available DeltaCatalogs404.

The flowchart of FIG. 8 shows the steps carried out by the DeltaUpdater126. When an update process is begun, the locations specified in list403 will be polled 502 in order until one is found which contains therequired DeltaCatalogs 404. The DeltaUpdater 126 builds a“DeltaDirectory” 408, which is a list of available DeltaCatalogs 404 atthe specified location. For transfer mechanisms which support queryingof a file directory, such as HTTP, FTP and file servers, theDeltaDirectory 408 is constructed with the information returned by suchqueries. For these transfer mechanisms, the DeltaCatalog 404 source anddestination state information is contained in the name of eachDeltaCatalog file. DeltaCatalogs 404 are named according to a schemewhere the first four characters specify a source state, the next fourcharacters specify a destination state, and the file extension is “cat.”For NNTP, the DeltaUpdater 126 retrieves headers for available messages,and looks for DeltaCatalog information in the headers. The DeltaCataloginformation specifies that the message is a DeltaCatalog 404, andspecifies the source and destination states are for the DeltaCatalog404.

After retrieving the source state and destination state for eachavailable DeltaCatalog 404, the DeltaUpdater 126 organizes thisinformation in the DeltaDirectory 408 by sorting 504 the DeltaCatalogs404 first by source state, and next by reverse destination state. TheDeltaCatalogs 404 of the preferred transport mechanism are used, ifpossible. Otherwise, DeltaCatalogs 404 of alternate transport mechanismsare used. This ordering of the DeltaCatalog 404 information allows theDeltaUpdater 126 to move through the DeltaDirectory 408 efficiently,finding the URL of each DeltaCatalog 404 with the necessary sourcestate, and the farthest destination state which does not exceed thedesired ending state. The DeltaUpdater 126 determines 506 the currentstate of the application to be updated, and the desired ending state ofthe application. The application can supply its current state to theDeltaUpdater 126, but the DeltaUpdater 126 needs other information todetermine the desired ending state. The method by which the DeltaUpdater126 determines the desire ending state of the application is addressedbelow.

The sequential set 412 of DeltaPackages 122 is cleared out 508, inpreparation for the determination of the set 412. The DeltaUpdater 126moves through the DeltaDirectory 408 sequentially in the loop comprisingsteps 510, 512, and 514 to find the first DeltaCatalog 404 in theDeltaDirectory 408 which has the current state as a source state. TheDeltaUpdater 126 then moves through the DeltaDirectory 408 from thisDeltaCatalog 404 to find the DeltaCatalog 404 which has the farthestdestination state which is not beyond the desired ending state (loop516, 518, and 520). If all of the DeltaCatalogs 404 which have thecurrent state as a source state have a destination state which is beyondthe desired ending state, then the update will fail (step 522).

When a DeltaCatalog 404 is identified at 516 which has a destinationstate which is not beyond the desired ending state, the DeltaCatalog 404is requested 524 from the appropriate source 400 or 402. After therequested DeltaCatalog 404 is received 526, the DeltaCatalog 404 isprocessed 528, as described above, to determine an incremental set ofDeltaPackages 122 which are appended to the sequential set 412. Thecurrent state of the application is then set 530 to the destinationstate of this DeltaCatalog 404, and if that state is not the desiredending state 532 the processing continues at step 514, and anotherDeltaCatalog 404 is determined.

When the full sequential set of DeltaPackages 122 necessary for anupdate are determined 532, the DeltaUpdater 126 requests 534 each neededDeltaPackage 122. The DeltaUpdater 126 receives 536 the requestedDeltaPackages 122 using the appropriate protocol, then uses the digitalsignature to verify that the DeltaPackages 122 are authentic and havenot been altered. Each DeltaPackage 122 retrieved is executed insequence 538, transforming the application from the beginning state tothe desired ending state, and the method stops at step 540. In otherembodiments, the DeltaUpdater 126 retrieves all of the DeltaPackages 122specified by a DeltaCatalog 404 before moving on to the nextDeltaCatalog 404.

DeltaDirectives

The beginning state of an application update is determined by theDeltaUpdater with reference to the application itself, which will carrysome designation of the current state. The desired ending state,however, is not necessarily as easy to identify. One possibility wouldbe for the DeltaUpdater to simply update the application to the lateststate for which DeltaCatalogs are available. In many situations,however, it may not be desirable to the user of a software applicationto update the application to the latest available state. For example, incorporate settings, Information Services departments may wish to testout and verify the stability of a version of a software applicationbefore allowing the applications owned by the corporation to be updatedto that version. This is often the case when the update is a majorrevision. Also, some networked computer systems may require that allcopies of a particular application be at exactly the same state. Onesolution would be for an Information Services department to control theavailability of DeltaCatalogs 404. Alternatively, it is desirable insome situations to utilize “DeltaDirectives,” which are issued inconnection with a given computer or network, specifying to whichdestination state an update is allowed. A DeltaDirective is a file orNNTP message containing a single value, the allowed destination state.The filename or NNTP message header identifies the file or NNTP messageas a DeltaDirective. The location for such DeltaDirectives is madeavailable to the DeltaUpdater before the update procedure is begun. Asillustrated in FIG. 7, the DeltaUpdater 126 identifies the latestavailable DeltaDirective 405 in the prescribed location, obtains theDeltaDirective 405, and reads the desired ending state from it. Thisdesired ending state is used by the DeltaUpdater 126 in steps 506, 516,and 532 of FIG. 8. The publisher of the updates may make availablegeneral DeltaDirectives 405 which specify the latest available state.The DeltaUpdater for any given computer may be set to look to theDeltaDirectives 405 issued by the software publisher or those issued bysome other authority, such as an Information Services department.

The above description is included to illustrate the operation of thepreferred embodiments and is not meant to limit the scope of theinvention. The scope of the invention is to be limited only by thefollowing claims. From the above description, many variations will beapparent to one skilled in the art that would yet be encompassed by thespirit and scope of the present invention.

1. A method for publishing update information for a computer readablefile associated with a sequence of states, the method comprising:creating at least two update patches, such that each update patch has afirst state and a second state associated therewith, the first state andthe second state of each update patch being states within the sequenceof states, the first state of each update patch preceding in thesequence of states the second state of that update patch, and eachupdate patch specifying information about differences between the firststate and the second state; and storing the update patches such thateach update patch is accessible to at least one update data source,where each update data source is disposed to receive a requestassociated with one of the update patches and transmit the requestedupdate patch over a computer network; wherein: the computer readablefile comprises a virus protection software application.
 2. The method ofclaim 1 wherein the virus protection software application comprises avirus detecting routine.
 3. The method of claim 1 wherein the virusprotection software application comprises virus signature information.4. A method for publishing update information for a computer readablefile associated with a sequence of states, the method comprising:creating at least two update patches, such that each update patch has afirst state and a second state associated therewith, the first state andthe second state of each update patch being states within the sequenceof states, the first state of each update patch preceding in thesequence of states the second state of that update patch, and eachupdate patch specifying information about differences between the firststate and the second state; and storing the update patches such thateach update patch is accessible to at least one update data source,where each update data source is disposed to receive a requestassociated with one of the update patches and transmit the requestedupdate patch over a computer network; wherein: the computer readablefile is a file from the group of files comprising: a data file; aprogram file; a database file; a graphics file; an audio file; a videofile.
 5. A method for creating update information for a computerreadable file associated with a sequence of states, the methodcomprising: creating at least two update patches, such that each updatepatch has a first state and a second state associated therewith, thefirst state and the second state of each update patch being stateswithin the sequence of states, the first state of each update patchpreceding in the sequence of states the second state of that updatepatch, and each update patch specifying information about differencesbetween the first state and the second state; wherein: each update patchhas a tier associated therewith, the tier being a positive integer thatcorresponds to the number of states between the first state and thesecond state associated with that update patch; and at least one of theupdate patches has a tier that is different from the tier of anotherupdate patch; wherein: for each update patch having a tier greater thanone, there exists a sequential plurality of unitary update patches eachhaving a tier of one, such that the update patch having a tier greaterthan one and the sequential plurality of unitary update patches have thesame overall beginning state and the same overall ending state, and theupdate patch having a tier greater than one contains fewer bits than theagglomerated sequential plurality of unitary update patches; wherein:the computer readable file comprises a virus protection softwareapplication.
 6. The method of claim 5 wherein the virus protectionsoftware application comprises a virus detecting routine.
 7. The methodof claim 5 wherein the virus protection software application comprisesvirus signature information.
 8. A method for creating update informationfor a computer readable file associated with a sequence of states, themethod comprising: creating at least two update patches, such that eachupdate patch has a first state and a second state associated therewith,the first state and the second state of each update patch being stateswithin the sequence of states, the first state of each update patchpreceding in the sequence of states the second state of that updatepatch, and each update patch specifying information about differencesbetween the first state and the second state; wherein: each update patchhas a tier associated therewith, the tier being a positive integer thatcorresponds to the number of states between the first state and thesecond state associated with that update patch; and at least one of theupdate patches has a tier that is different from the tier of anotherupdate patch; wherein: for each update patch having a tier greater thanone, there exists a sequential plurality of unitary update patches eachhaving a tier of one, such that the update patch having a tier greaterthan one and the sequential plurality of unitary update patches have thesame overall beginning state and the same overall ending state, and theupdate patch having a tier greater than one contains fewer bits than theagglomerated sequential plurality of unitary update patches; wherein:the computer readable file is a file from the group of files comprising:a data file; a program file; a database file; a graphics file; an audiofile; a video file.
 9. A method for creating update information for acomputer readable file associated with a sequence of states, the methodcomprising: creating at least two update patches, such that each updatepatch has a first state and a second state associated therewith, thefirst state and the second state of each update patch being stateswithin the sequence of states, the first state of each update patchpreceding in the sequence of states the second state of that updatepatch, and each update patch specifying information about differencesbetween the first state and the second state; and creating at least twocatalogs, each catalog specifying at least one update patch; wherein: acatalog contains information pertaining to flavor of the computerreadable file; and flavor consists of at least one characteristic fromthe group of characteristics comprising computer architecture with whichthe computer readable file can be used, operating system with which thecomputer readable file can be used, and natural language with which thecomputer readable file communicates to users; wherein: the computerreadable file comprises a virus protection software application.
 10. Themethod of claim 9 wherein the virus protection software applicationcomprises a virus detecting routine.
 11. The method of claim 9 whereinthe virus protection software application comprises virus signatureinformation.
 12. A method for creating update information for a computerreadable file associated with a sequence of states, the methodcomprising: creating at least two update patches, such that each updatepatch has a first state and a second state associated therewith, thefirst state and the second state of each update patch being stateswithin the sequence of states, the first state of each update patchpreceding in the sequence of states the second state of that updatepatch, and each update patch specifying information about differencesbetween the first state and the second state; and creating at least twocatalogs, each catalog specifying at least one update patch; wherein: acatalog contains information pertaining to flavor of the computerreadable file; and flavor consists of at least one characteristic fromthe group of characteristics comprising computer architecture with whichthe computer readable file can be used, operating system with which thecomputer readable file can be used, and natural language with which thecomputer readable file communicates to users; wherein: the computerreadable file is a file from the group of files comprising: a data file;a program file; a database file; a graphics file; an audio file; a videofile.
 13. A computer-readable medium containing computer programinstructions for publishing update information for a computer readablefile associated with a sequence of states, said computer programinstructions performing the steps of: creating at least two updates,such that each update has a first state and a second state associatedtherewith, the first state and the second state of each update beingstates within the sequence of states, the first state of each updatepreceding in the sequence of states the second state of that update, andeach update specifying information about differences between the firststate and the second state; and storing the updates such that eachupdate patch is accessible to at least one update data source, whereeach update data source is disposed to receive a request associated withone of the updates and transmit the requested update over a computernetwork; wherein: the computer readable file comprises a virusprotection software application.
 14. The computer-readable medium ofclaim 13 wherein the virus protection software application comprises avirus detecting routine.
 15. The computer-readable medium of claim 13wherein the virus protection software application comprises virussignature information.
 16. A computer-readable medium containingcomputer program instructions for publishing update information for acomputer readable file associated with a sequence of states, saidcomputer program instructions performing the steps of: creating at leasttwo updates, such that each update has a first state and a second stateassociated therewith, the first state and the second state of eachupdate being states within the sequence of states, the first state ofeach update preceding in the sequence of states the second state of thatupdate, and each update specifying information about differences betweenthe first state and the second state; and storing the updates such thateach update is accessible to at least one update data source, where eachupdate data source is disposed to receive a request associated with oneof the updates and transmit the requested update over a computernetwork; wherein: the computer readable file is a file from the group offiles comprising: a data file; a program file; a database file; agraphics file; an audio file; a video file.
 17. A computer-readablemedium containing computer program instructions for creating updateinformation for a computer readable file associated with a sequence ofstates, said computer program instructions performing the steps of:creating at least two updates, such that each update has a first stateand a second state associated therewith, the first state and the secondstate of each update being states within the sequence of states, thefirst state of each update preceding in the sequence of states thesecond state of that update, and each update specifying informationabout differences between the first state and the second state; wherein:each update has a tier associated therewith, the tier being a positiveinteger that corresponds to the number of states between the first stateand the second state associated with that update; and at least one ofthe updates has a tier that is different from the tier of anotherupdate; wherein: for each update having a tier greater than one, thereexists a sequential plurality of unitary updates each having a tier ofone, such that the update having a tier greater than one and thesequential plurality of unitary updates have the same overall beginningstate and the same overall ending state, and the update having a tiergreater than one contains fewer bits than the agglomerated sequentialplurality of unitary updates; wherein: the computer readable filecomprises a virus protection software application.
 18. Thecomputer-readable medium of claim 17 wherein the virus protectionsoftware application comprises a virus detecting routine.
 19. Thecomputer-readable medium of claim 17 wherein the virus protectionsoftware application comprises virus signature information.
 20. Acomputer-readable medium containing computer program instructions forcreating update information for a computer readable file associated witha sequence of states, said computer program instructions performing thesteps of: creating at least two updates, such that each update has afirst state and a second state associated therewith, the first state andthe second state of each update being states within the sequence ofstates, the first state of each update preceding in the sequence ofstates the second state of that update, and each update specifyinginformation about differences between the first state and the secondstate; wherein: each update has a tier associated therewith, the tierbeing a positive integer that corresponds to the number of statesbetween the first state and the second state associated with thatupdate; and at least one of the updates has a tier that is differentfrom the tier of another update; wherein: for each update having a tiergreater than one, there exists a sequential plurality of unitary updateseach having a tier of one, such that the update having a tier greaterthan one and the sequential plurality of unitary updates have the sameoverall beginning state and the same overall ending state, and theupdate having a tier greater than one contains fewer bits than theagglomerated sequential plurality of unitary updates; wherein: thecomputer readable file is a file from the group of files comprising: adata file; a program file; a database file; a graphics file; an audiofile; a video file.
 21. A computer-readable medium containing computerprogram instructions for creating update information for a computerreadable file associated with a sequence of states, said computerprogram instructions performing the steps of: creating at least twoupdates, such that each update has a first state and a second stateassociated therewith, the first state and the second state of eachupdate being states within the sequence of states, the first state ofeach update preceding in the sequence of states the second state of thatupdate, and each update specifying information about differences betweenthe first state and the second state; and creating at least twocatalogs, each catalog specifying at least one update; wherein: acatalog contains information pertaining to flavor of the computerreadable file; and flavor consists of at least one characteristic fromthe group of characteristics comprising computer architecture with whichthe computer readable file can be used, operating system with which thecomputer readable file can be used, and natural language with which thecomputer readable file communicates to users; wherein: the computerreadable file comprises a virus protection software application.
 22. Thecomputer-readable medium of claim 21 wherein the virus protectionsoftware application comprises a virus detecting routine.
 23. Thecomputer-readable medium of claim 21 wherein the virus protectionsoftware application comprises virus signature information.
 24. Acomputer-readable medium containing computer program instructions forcreating update information for a computer readable file associated witha sequence of states, said computer program instructions performing thesteps of: creating at least two updates, such that each update has afirst state and a second state associated therewith, the first state andthe second state of each update being states within the sequence ofstates, the first state of each update preceding in the sequence ofstates the second state of that update, and each update specifyinginformation about differences between the first state and the secondstate; and creating at least two catalogs, each catalog specifying atleast one update; wherein: a catalog contains information pertaining toflavor of the computer readable file; and flavor consists of at leastone characteristic from the group of characteristics comprising computerarchitecture with which the computer readable file can be used,operating system with which the computer readable file can be used, andnatural language with which the computer readable file communicates tousers; wherein: the computer readable file is a file from the group offiles comprising: a data file; a program file; a database file; agraphics file; an audio file; a video file.